An embodiment provides an implant prosthesis. In some cases, the prosthesis can take the form of an implant strip that may be implanted through the use of a surgical procedure that minimizes incision sizes and may be considered less invasive than typical spinal implant procedures. In one aspect, a method of implanting a prosthesis may include making an incision in a patient, inserting a tube into the incision and between two adjacent vertebrae, inserting an implant strip through the tube, ejecting the implant strip from the tube between the two adjacent vertebrae, coiling the implant strip between the two adjacent vertebrae, and resisting compressive and tensile forces by deflecting an intermediate portion of the implant strip.
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9. A method of implanting a spinal prosthesis, comprising:
making an incision in a patient;
inserting a tube into the incision and proximate two adjacent vertebrae;
inserting an implant strip through the tube;
wherein the implant strip includes a longitudinal axis, the implant strip comprising
a first portion comprising a first lateral side portion extending parallel to the longitudinal axis and a second lateral side portion extending parallel to the longitudinal axis,
a second portion extending parallel to the longitudinal axis and disposed between the first lateral side portion and the second lateral side portion, wherein the first portion and the second portion are made of the same material, and
wherein the first lateral side portion includes an outer edge on a side of the first lateral side portion opposite to the second portion, and wherein the second lateral side portion includes an outer edge on a side of the second lateral side portion opposite to the second portion,
wherein the second portion of the implant strip comprises a structure that is less rigid in a direction generally perpendicular to the longitudinal axis than the first portion's structure in the direction generally perpendicular to the longitudinal axis so that the second portion deflects under compressive and tensile forces applied to the implant strip in the direction generally perpendicular to the longitudinal axis before the first portion deflects under the compressive and tensile forces,
wherein the outer edge of the first lateral side portion and the outer edge of the second lateral side portion both include a bone growth promoting treatment, and
wherein the implant strip is formed of a metal;
facilitating coiling of the implant strip at a distal end of the tube; implanting the implant strip between the two adjacent vertebrae; and contacting the metal outer edge of the first lateral side portion to a first vertebra of the two adjacent vertebrae and the metal outer edge of the second lateral side portion to a second vertebra of the two adjacent vertebrae so as to attach the metal outer edge of the first lateral side portion to the first vertebra and the metal outer edge of the second lateral side portion to the second vertebra by virtue of bone growth promoted by the bone growth promoting treatment,
wherein the spinal prosthesis resists the compressive and tensile forces by deflecting the second portion before deflection of the first portion after implantation has been completed.
1. A method of implanting a spinal prosthesis, comprising:
making an incision in a patient;
inserting a tube into the incision and proximate two adjacent vertebrae;
inserting an implant strip through the tube holding the implant strip in a generally linear shape along its longitudinal axis,
wherein the implant strip includes a longitudinal axis, the implant strip comprising
a first portion comprising a first lateral side portion extending parallel to the longitudinal axis and a second lateral side portion extending parallel to the longitudinal axis,
a second portion extending parallel to the longitudinal axis and disposed between the first lateral side portion and the second lateral side portion, wherein the first portion and the second portion are made of the same material, and
wherein the first lateral side portion includes an outer edge on a side of the first lateral side portion opposite to the second portion, and wherein the second lateral side portion includes an outer edge on a side of the second lateral side portion opposite to the second portion,
wherein the second portion of the implant strip comprises a structure that is less rigid in a direction generally perpendicular to the longitudinal axis than the first portion's structure in the direction generally perpendicular to the longitudinal axis so that the second portion deflects under compressive and tensile forces applied to the implant strip in the direction generally perpendicular to the longitudinal axis before the first portion deflects under the compressive and tensile forces,
wherein the outer edge of the first lateral side portion and the outer edge of the second lateral side portion both include a bone growth promoting treatment, and
wherein the implant strip is formed of a metal;
ejecting the implant strip from the tube between the two adjacent vertebrae; coiling the implant strip between the two adjacent vertebrae to form the spinal prosthesis; and
contacting the metal outer edge of the first lateral side portion to a first vertebra of the two adjacent vertebrae and the metal outer edge of the second lateral side portion to a second vertebra of the two adjacent vertebrae so as to attach the metal outer edge of the first lateral side portion to the first vertebra and the metal outer edge of the second lateral side portion to the second vertebra by virtue of bone growth promoted by the bone growth promoting treatment,
wherein the spinal prosthesis resists the compressive and tensile forces by deflecting the second portion before deflection of the first portion after implantation has been completed.
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1. Field of the Invention
The present invention relates generally to implantable prostheses and in particular to a spinal implant strip including a selectively applied bone growth promoting agent.
2. Description of Related Art
Spinal fusion implants have been previously proposed. In some cases, spinal fusion implants are embedded between adjacent vertebrae, partially or fully replacing the tissue disposed between the vertebrae.
One type of spinal fusion implant is the threaded spinal implant (commonly referred to as a spinal cage). This type of prosthesis is disclosed in Michelson (U.S. Pat. No. 6,264,656), the entirety of which is incorporated by reference. The threaded spinal implant is inserted between two adjacent vertebrae and is incorporated into the fusion of the bone along this portion of the spine.
Brantigan (U.S. Pat. No. 4,834,757) discloses plugs, used as spinal fusion implants, the entirety of which is incorporated by reference. The plugs are rectangular with tapered front ends and tool receiving rear ends. Generally, the plugs may be used in a similar manner to the spinal cages of Michelson. As with the spinal cages, the plugs may be inserted between adjacent vertebrae. The plugs may include nubs that behave like teeth, countering any tendency for the plugs to slip between the vertebrae.
Generally, the spinal fusion implants disclosed require invasive surgery for implantation. Furthermore, these spinal fusion implants rigidly fix two adjacent bones together and do not allow for any motion. There is a need in the art for a type of spinal fusion implant that may be implanted through a minimally invasive procedure. There is also a need for fusion implants that can potentially accommodate motion.
A disc fusion implant is disclosed. In one aspect, the invention provides a spinal prosthesis, comprising: an implant strip including a first shape and a second shape and wherein the first shape is different than the second shape; the first shape being configured for installation through a tube; and where the second shape is coiled.
In another aspect, the second shape is a coil.
In another aspect, the first shape is a strip.
In another aspect, the implant strip is made of a material including titanium.
In another aspect, the strip is a shape memory material.
In another aspect, the shape memory alloy is made of a material selected from the group consisting essentially of: nickel, titanium, cobalt chrome, stainless steel, polymers, biological matrices and ceramics.
In another aspect, the invention provides a spinal prosthesis, comprising: an implant strip configured for insertion between two adjacent vertebrae; and where the implant strip is a shape memory alloy.
In another aspect, the implant strip is a corrugated strip.
In another aspect, a plurality of strips are used.
In another aspect, three or more implant strips are used.
In another aspect, the invention provides a method of implanting a spinal prosthesis, comprising the steps of: making an incision in a patients back; inserting a tube into the incision; inserting the spinal prosthesis through the tube; and implanting the spinal prosthesis between two adjacent vertebrae.
In another aspect, the spinal prosthesis is an implant strip.
In another aspect, the tube includes a curved tip that is configured to facilitate coiling of the implant strip.
In another aspect, the implant strip has a first shape and a second shape.
In another aspect, the implant strip has the first shape when the implant strip is inserted through the tube.
In another aspect, the implant strip has the second shape after the insertion of the implant strip is completed.
In another aspect, the first shape is a flat strip.
In another aspect, the second shape is a coil.
In another aspect, the invention provides a spinal prosthesis, comprising: an implant strip configured for implantation between two adjacent vertebrae; a bone growth promoting agent; and where the bone growth promoting agent is applied to the implant strip.
In another aspect, the implant strip includes a first portion.
In another aspect, the bone growth promoting agent is applied along the first portion.
In another aspect, the bone growth promoting agent is applied to the entirety of the implant strip.
In another aspect, the bone growth promoting agent is selectively applied to the implant strip.
In another aspect, the bone growth promoting agent is applied to a top surface of the implant strip and a bottom surface of the implant strip.
In another aspect, the invention provides a spinal prosthesis, comprising: an implant strip configured for insertion between two adjacent vertebrae; the implant strip comprising a first portion having a first rigidity and a second portion having a second rigidity that is less than the first rigidity; and where the second portion is configured to deflect under an axial load.
In another aspect, the first portion is made of a substantially non-deforming material.
In another aspect, the second portion is made of a substantially flexible material.
In another aspect, the second portion has a modified structure configured to decrease the rigidity of the second portion.
In another aspect, the second portion includes a deflecting portion.
In another aspect, the deflecting portion has an elliptic shape.
In another aspect, the second portion includes a motion limiting tab.
In another aspect, the second portion includes a cross bar configured to deflect and limit the axial motion and lateral movement of the implant strip.
In another aspect, the second portion is a protruding portion.
In another aspect, the protruding portion includes a plurality of slots.
In another aspect, the second portion is configured to partially permanently deflect.
In another aspect, the invention provides a spinal prosthesis configured for insertion between two adjacent vertebrae, a first vertebrae and a second vertebrae, comprising: an implant strip including a lateral dimension extending from a first lateral side portion to a second lateral portion, and wherein the implant strip includes a longitudinal dimension extending down the length of the implant strip; wherein the first lateral side of the implant strip is configured to engage the first vertebrae and wherein the second lateral side of the implant strip is configured to engage the second vertebrae; and wherein a first longitudinal portion of the implant strip forms a first inner coil, and wherein a second longitudinal portion of the implant strip forms a second outer coil, wherein the second outer coil is spaced radially outward of the first inner coil.
In another aspect, the first inner coil and the second inner coil are spaced to prevent contact with one another.
In another aspect, the first lateral side portion and the second lateral side portion comprise a first portion, and wherein a second portion is disposed between the first lateral side portion and the second lateral side portion; and wherein the second portion is less rigid than the first portion.
In another aspect, the second portion permits motion between the first lateral side portion and the second lateral side portion.
In another aspect, the first inner coil and the second inner coil are spaced to prevent contact with one another during motion.
In another aspect, the spinal prosthesis provides for continuity of a spine by providing a mechanical bridge between the first vertebrae and the second vertebrae.
In another aspect, the spinal prosthesis also allows motion between the first vertebrae and the second vertebrae.
In another aspect, an elastomeric material is disposed between the first lateral side portion and the second lateral portion, and wherein the first lateral side portion includes at least one protrusion engaging the elastomeric material.
In another aspect, the second lateral portion includes at least one protrusion engaging the elastomeric material.
Other systems, methods, features and advantages of the invention will be, or will become, apparent to one of ordinary skill in the art upon examination of the following figures and detailed description. It is intended that all such additional systems, methods, features and advantages be included within this description and this summary, be within the scope of the invention, and be protected by the following claims.
The invention can be better understood with reference to the following drawings and description. The components in the figures are not necessarily to scale, emphasis instead being placed upon illustrating the principles of the invention. Moreover, in the figures, like reference numerals designate corresponding parts throughout the different views.
Preferably, first tube 1110 and second tube 1114 may be inserted into an intervertebral disc disposed between two adjacent vertebrae.
In some cases, an intervertebral disc 1202 may degenerate over time, requiring the need for a spinal disc implant.
If an intervertebral disc has failed or degenerated, a typical correction is a surgical procedure to remove some or all of the intervertebral disc. Following this, a spinal prosthesis may be inserted in order to facilitate fusion of the vertebrae adjacent to the failed intervertebral disc. In a preferred embodiment, surgery may be performed in a manner that limits the size of the incisions needed to insert a prosthesis. Preferably, a spinal prosthesis includes provisions for easy insertion via a small incision in the back.
In some cases, a vertebral body could also be fully or partially replaced using a spinal prosthesis. The following detailed description refers to the replacement of an intervertebral disc, however in other embodiments these same principles could be applied to a spinal prosthesis configured to replace a vertebral body.
As implant strip 1400 preferably has a relatively small profile, it may be inserted into smaller incisions, such as those shown in
Generally, implant strip 1400 may be constructed of a material including metal. In some embodiments, implant strip 1400 may be a shape memory alloy. In some embodiments, implant strip 1400 may be made of a titanium alloy. In other embodiments, implant strip 1400 may comprise a combination of one or more materials including, but not limited to, cobalt chrome (CoCr), stainless steel, Nitinol, polymers, biological matrices, ceramics or any biocompatible material. In a preferred embodiment, implant strip 1400 may be made of a material including titanium.
In some cases, a stainless steel alloy may be used as a coiling spring. This arrangement is useful because such alloys low fatigue and high fatigue resistance. Additionally, these alloys may have a high return force. Additionally, using a stainless steel alloy allows for increased corrosion resistance.
Preferably, implant strip 1400 may include provisions for changing shape. In some embodiments, implant strip 1400 may be manufactured at an elevated temperature with a first shape. Following this, implant strip 1400 may be cooled and deformed into a second shape. Finally, as implant strip is placed in temperature ranges of 90-100 degrees Fahrenheit, it may deform back to the first shape. In a preferred embodiment, the first shape is a spiral coil and the second shape is a long rectangular strip.
In some embodiments, implant strip 1400 may include provisions for promoting bone growth, once it has been inserted into the intervertebral disc region. In some embodiments, implant strip 1400 may include a bone growth promoting agent. In a preferred embodiment, implant strip 1400 preferably includes bone growth promoting agent 1402 disposed along the entirety of its length.
In some embodiments, bone growth promoting agent 1402 may be selectively applied to one or more portions of implant strip 1400 or may not be applied at all. Preferably, as shown in
Details of a preferred embodiment of a surgical procedure used to insert a spinal prosthesis of some kind are best understood with respect to
In a first step, first tube 1510 and second tube 1514 may be inserted into intervertebral disc 1202. Generally, one tube may be used for a surgical tool, while the second tube may be simultaneously used to insert a fiber optic camera into one of the incisions to give the surgeon a clear view of the intervertebral disc region. In some embodiments, first tube 1510 and second tube 1514 may be cannulae. The cross sectional shape of tubes 1510 and 1514 may be any shape, including oval-like, circular or otherwise round, as well as hexagonal or any polygonal shape.
Following the insertion of first tube 1510 and second tube 1514, a series of instruments may be used to remove portions of intervertebral disc 1202 and score the endplates. In some embodiments, first surgical device 1540 may be inserted into first tube 1510. First surgical device 1540 may be a brush, burr, rasp or a shaver. In a preferred embodiment, first surgical device 1540 may include flexible shaft 1542 and wire brush tip 1544. Preferably, wire brush tip 1544 spins, removing portions of intervertebral disc 1202.
In some embodiments, dual catheter 1550 may be inserted into second tube 1514. Preferably, dual catheter 1550 may include first channel 1552 and second channel 1554. In some embodiments, first channel 1552 may include a fiber optic camera. With this configuration, the surgery may be visualized by the surgeon using the fiber optic camera. Additionally, second channel 1554 may be configured to inject water and/or provide a vacuum for removing debris. With this configuration, second channel 1554 may be used to clean out cavity 1560, which is created as a portion of intervertebral disc 1202 is removed. Once the necessary portions of intervertebral disc 1202 have been removed, first surgical device 1540 may be removed from first tube 1510.
Referring to
In this embodiment, first portion 1600 of implant strip 1400 has started to coil as it is inserted into cavity 1560. Preferably, as implant strip 1400 is further inserted through first tube 1510, the portion disposed within cavity 1560 may deform and coil as well. In a preferred embodiment, implant strip 1400 may be inserted in a manner that allows implant strip 1400 to coil around itself completely, as seen in
Generally, implant strip 1400 may be configured to fill cavity 1560 of intervertebral disc 1202 completely. For illustrative purposes, implant strip 1400 is shown here to be coiled with large gaps between adjacent portions. However, in some embodiments, implant strip 1400 may be coiled tightly so that no gaps are seen. In a preferred embodiment, implant strip 1400 may be coiled loosely to provide space or gaps between adjacent, radially spaced coils. This arrangement may help to facilitate bone growth to occur between the coils.
In an alternative embodiment, multiple implant strips may be used. Preferably, each implant strip may include a coiled shape, similar to the shape of the previous embodiment. In some embodiments, each of the implant strips may be disposed against one another. In some embodiments, each of the implant strips may be associated with different heights in order to create lordosis.
Preferably, each of the implant strips 1802, 1804 and 1806 may be constructed of a shape memory alloy. In some embodiments, the shape memory alloy may be a nickel titanium alloy. In other embodiments, implant strips 1802, 1804 and 1806 may comprise a combination of one or more materials including, but not limited to, cobalt chrome (CoCr), stainless steel, Nitinol, polymers, biological matrices, ceramics or any biocompatible material. In a preferred embodiment, implant strips 1802, 1804 and 1806 may be made of a material including titanium.
In other embodiments, the structure of an implant strip may be modified. In some embodiments, an implant strip may include a slightly different shape. In other embodiments, an additional material may be used in conjunction with the shape memory alloy of the previous embodiments.
Preferably, corrugated implant strip 1902 may be constructed of a shape memory material. In some embodiments, the shape memory alloy may be a nickel titanium alloy. In a preferred embodiment, corrugated implant strip 1902 may be made of a material including titanium. Generally, corrugated implant strip 1902 may be made of any of the materials discussed with respect to the previous embodiments of implant strips, including cobalt chrome (CoCr), stainless steel, Nitinol, polymers, biological matrices, ceramics or any biocompatible material.
Preferably, an implant device includes provisions for allowing for different kinds of motion that may occur in a spine.
In some embodiments, an implant device may include provisions to accommodate deflections in the axial direction. This may be a useful feature as axial forces may be applied to the implant strip by the adjacent vertebrae during normal activities such as walking, running and bending of the spinal column. In other words, the implant strip may be configured to endure axial loads that are usually applied to spinal discs. Additionally, the implant device may be configured to accommodate bending, lateral (including shear forces), and twisting forces.
In addition to deflection in the axial direction, a spinal implant device may also be configured to undergo bending, lateral and twisting motions. Implant device 2200 is seen in
Implant device 2200 is seen in
Referring to
In each of these cases, first implant devices 2200 is provided with restoring forces via second portion 2204. Additionally, although these different types of deflections (due to compressive, bending, twisting and lateral forces) have been shown separately, it should be understood that implant device 2200 may be configured to undergo any combination of or all of these various types of deformations simultaneously.
First portion 2202 may be made of any material, including both shape memory alloys and spring steel, as well as other types of materials, including previously discussed materials for implant strip 1400. Second portion 2204 may be made of any material that may be less rigid than first portion 2202. In addition, second portion 2204 may be designed to deflect and/or deform under various forces. Examples of such materials include, but are not limited to, elastomers, soft metals, plastics, polymers, wire meshes (made from materials such as Dacron or ceramics), as well as other types of materials.
Additionally, in some embodiments, first portion 2202 and second portion 2204 could be made of the same material. However, the rigidity of second portion 2204 could be modified by changing the structural properties of second portion 2204. This configuration may be achieved by inserting holes or slots or modifying the structure of second portion 2204 in other ways. With these types of modifications, first portion 2202 may be more rigid than second portion 2204 even though they are made of the same material.
Preferably, the degree of deflection of implant device 2200 may vary. During the initial implantation, implant device 2200 may deflect or compress until the height of the implant device is about eighty percent of the initial height of the implant strip prior to implantation. This initial deflection is primarily due to normal stresses applied by the adjacent vertebrae when the spinal column is at rest. During motion, however, implant device 2200 may continue to deflect due to increased axial loads from the adjacent vertebrae. The degree of deflection may be between 15 and 25 percent of the initial height of implant device 2200. It should be understood, however, that the degree of deflection is not limited and may vary according to properties of the various materials that are used. In some cases, the degree of deflection could be much larger than 25 percent or much less that 15 percent. By carefully selecting the material, size, design as well as other structural features of second portion 2204, the deflection of implant device 2200 can be better controlled. The following embodiments illustrate ways in which the deflection of implant device 2200 can be achieved using different materials and structural features for second portion 2204.
In some embodiments, elastomer strip 2004 may be disposed between first lateral side portion 2002 and second lateral side portion 2006. Elastomer strip 2004 is preferably made of a flexible material. In some embodiments, elastomer strip 2004 may be joined to first lateral side portion 2002 and second lateral side portion 2006. In some embodiments, elastomer strip 2004 may encase perforated edges, teeth or roughed edges of first lateral side portion 2002 and second lateral side portion 2006 in order to ensure a positive mechanical connection. In this preferred embodiment, first lateral side portion 2002 and second lateral side portion 2206 may be associated with teeth 2007. Using this configuration, teeth 2007 provide a point of attachment for elastomer strip 2004 to first lateral side portion 2002 and second lateral side portion 2006. In other embodiments, other provisions may be used to fixedly attach elastomer strip 2004 to first lateral side portion 2002 and second lateral side portion 2006.
In some embodiments, implant strip 2000 may include a bone growth promoting agent. In this embodiment, top portion 2003 and bottom portion 2005 are preferably coated with a bone growth promoting agent 2001. Generally, any type of bone growth promoting agent may be used. Additionally, any type of pattern for a bone growth promoting agent may be used. Various bone growth promoting agents and patterns have been previously referenced. Using this configuration, implant strip 2000 may be configured to stimulate increased bone growth at adjacent vertebrae where implant strip 2000 is implanted. In some embodiments, such a configuration may be used in a manner similar to a spinal cage, which provides a means of fusing two vertebral bodies together.
Referring to
Preferably, first longitudinal portion 2080 is configured to form a first inner coil 2086, as seen in
Preferably, provisions for preventing contact between portions of an implant strip may be provided in other embodiments as well. The principles discussed here may be generally applied to any type of implant strip including a first longitudinal portion and a second longitudinal portion. In some embodiments, these implant strips may or may not include deforming portions.
In other embodiments, an implant strip may include different provisions for allowing deflection of the implant strip in the axial direction. In some embodiments, an implant strip may include perforated portions with large gaps or holes that reduce rigidity and thereby allow for some deflection of the implant strip. It should be understood that throughout these embodiments, illustrated in
Additionally, first implant strip 2020 may include first deflecting portions 2024 that are disposed between lower edge 2002 and upper edge 2006. Preferably, lower edge 2002 and upper edge 2006 are joined to first deflecting portions 2024. For purposes of clarity, only a section of first implant strip 2020 is shown here, however it should be understood that first deflecting portions 2024 are preferably disposed along the entire length of first implant strip 2020. Generally, the spacing and number of first deflecting portions 2024 may be varied in order to change the deflection properties of first implant strip 2020.
In this embodiment, first deflecting portions 2024 may be elliptically shaped prior to deflection. In other embodiments, the shape of first deflecting portions 2024 may vary. Examples of other shapes that may be used include, but are not limited to, circles, diamonds, as well as any polygonal shape. Additionally, in other embodiments, the thickness associated with first deflecting portions 2024 could be changed. By varying these properties of first deflecting portions 2024, the deflection properties of first implant strip 2020 may be modified.
In some embodiment, first implant strip 2020 may also include motion limiting features that prevent excessive deflection in the axial direction. In this embodiment, first implant strip 2020 may include motion limiting tabs 2026. Preferably, motion limiting tabs 2026 may be disposed within deflecting portions 2024 and/or adjacent to deflecting portions 2024.
Preferably, deflecting portions 2024 and motion limiting tabs 2026 may be formed by cutting or removing portions of first implant strip 2020, which creates gaps within interior space 2022. This cutting may be done using techniques known in the art, such as stamping, punching, laser fusion and/or water drilling, or any combination of techniques. In other embodiments, first implant strip 2020, including deflecting portions 2024 and tabs 2026 may be formed using a die of some kind. These techniques are preferably used to create smooth edges in order to prevent burrs. Using this configuration, scar tissue due to burrs may be substantially reduced following implantation of first implant strip 2020. In other embodiments, however, techniques used that leave burrs intact may be used so that the remaining burrs may facilitate in-growth of bone.
Following the insertion of first implant strip 2020 between two adjacent vertebrae, an axial force may be experienced as the vertebrae are compressed during motion of the spinal column. Referring to
Referring to
In a third embodiment, shown in
In a fourth embodiment, seen in
Implant strip 2300 also preferably includes slots 2303. In this embodiment, slots 2302 extend from upper side 2304 to lower side 2306 of implant strip 2300. Slots 2302 preferably extend through protruding portion 2303. The addition of slots 2302 to implant strip 2300 generally decreases the rigidity of protruding portion 2303. Using this configuration, slots 2302 may provide increased deflection of protruding portion 2303.
In some embodiments, the number, shape and size of slots associated with an implant strip may vary. By changing the number, shape, orientation and/or size of slots of an implant strip, the axial loading characteristics of the implant strip may be controlled. Increasing the number of slots may increase the degree of axial deflection, as the rigidity of protruding portion 2303 is reduced with an increasing number of slots. Likewise, decreasing the number of slots may decrease the degree of axial deflection, as the rigidity of protruding portion 2303 is increased with a decreased number of slots.
Additionally, changing the number of slots may also increase the flexibility of the implant strip in the circumferential direction. Increasing the number of slots may generally increase the amount of deflection in the circumferential direction. Likewise, decreasing the number of slots may generally decrease the amount of deflection in the circumferential direction.
Referring to
By varying the radius of curvature of an implant strip in this manner, the tightness of coiling associated with an implant strip may be varied. Generally, a tighter coil provides more surface area over which to receive axial loads from adjacent vertebrae and thereby increases the strength of the implant strip in the axial direction.
In the previous embodiment, slots of different widths are used to modifying the deflecting properties of an implant strip. In other embodiments, the spacing between slots could vary. In still other embodiments, the orientation of the slots may vary as well. Additionally, in some embodiments, the slots could have different shapes such as oval, round, hexagonal or any type of polygon or irregular shape. These various shapes can be used singularly or in any desired combination.
In another embodiment, shown in
In some cases, the orientation of slots could be modified. In some embodiments, implant strip 3300 may include angled slots 3310. Generally, angled slots 3310 may be oriented in any direction, including, in other embodiments, perpendicular to thin slots 3302.
Additional shapes for cutouts are also illustrated in
The various shapes and patterns illustrated in
Preferably, implant strips may be configured to permanently deflect in some situations. Generally, vertebrae are not completely symmetric and therefore the spacing between two adjacent vertebrae may vary. Using an implant strip that is configured to partially permanently deflect at some portions allows for a more natural fit of the implant strip.
Using the configuration described here, the shape of implant strip 3104 is preferable automatically customized. In some regions between adjacent vertebrae, such as the narrow region discussed above, the implant strip may plastically deform to adjust to natural contours of the adjacent vertebrae. In other regions, such as the wider region discussed above, the implant strip may remain extended or minimally deflected to fully fill in the spaces between vertebrae. In this manner, the implant strip preferably performs a similar function to a spinal disc.
Preferably, an implant strip may include provisions for facilitating coiling of the implant strip during implantation to a spine. In a preferred embodiment, a curved tube may be used to facilitate coiling of an implant strip. The following embodiment is intended to illustrate a provision for facilitating coiling of any type of implant strip. It should be understood that the following procedure may be used to facilitate the implantation of any of the various implant strips discussed earlier as well as other possible implant strips.
As implant strip 2110 is inserted, curved deforming tip 2106 helps facilitate some bending of implant strip 2110 in the circumferential direction. As insertion of implant strip 2110 continues, intermediate portion 2114 of implant strip 2110 is further coiled by inner curved portion 2108 of delivery device 2102. This arrangement further facilitates the coiling of distal end 2112 of implant strip 2110 towards the center of cavity 1560. Using delivery device 2102 allows for increased control of coiling of implant strip 2110 during implantation.
In some embodiments, a spinal implant strip may be used to repair a herniated intervertebral disc. This may be achieved by using similar techniques for removing the herniated portion of the disc. Following this, a spinal implant strip may be inserted into the removed portion of the disc.
In some cases where an intervertebral disc is herniated, such as is shown here, portions of nucleus pulposus 1224 may be removed, as seen in
Preferably, implant trip 3802 may be inserted into recess 3702 to repair intervertebral disc 1202, as seen in
Using the various arrangements for a spinal implant strip discussed in this detailed description provides for improved utility over prior designs. Each of these designs is versatile since various types of implant strips may be used for replacing various kinds of spinal discs. Also, each of these arrangements provides for a single piece device that does not experience the wear or generate particulate debris that may be associated with multi-piece designs. Finally, using the materials and designs discussed in this detailed description, the implant strips are preferably configured to either remain rigid or maintain a general spring-like state, without undergoing any fatigue or mechanical failure.
Embodiments of the present invention can provide for continuity of the spine. The term “continuity of the spine” generally refers to the concept providing an actual mechanical bridge between two distinct vertebral bodies. In some embodiments, this implant device provides for a mechanical bridge while also allowing motion between the two distinct vertebral bodies. This arrangement can approximate the natural biomechanics of the spine.
By applying principles or features of the present invention, a surgeon can implant a device to restore the original anatomical height of the disk, thereby restoring normal forces across the spine. The surgeon can also select an implant device that can provide decompression of the nerves in the spinal foramen and canals. This implant device can provide a post-implantation height greater than or less than the original anatomical height of the disk. This implant device can also provide a post-implantation configuration that optimizes the relative position between two vertebrae. In some cases, this post-implantation configuration can be used to correct scoliosis or spondylolisthesis.
While various embodiments of the invention have been described, the description is intended to be exemplary, rather than limiting and it will be apparent to those of ordinary skill in the art that many more embodiments and implementations are possible that are within the scope of the invention. Accordingly, the invention is not to be restricted except in light of the attached claims and their equivalents. Also, various modifications and changes may be made within the scope of the attached claims.
Sack, James A., Bhatnagar, Mohit K, Yeh, Jack Y
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